JPH08502643A - Proteinaceous feed substance containing low levels of zinc and having high rumen bypass potential, and method for producing the same - Google Patents

Abstract

  (57) [Summary] The present invention comprises a plant meal composition with high rumen bypass potential for use in feeding ruminants and a method of making the composition. The composition of the present invention contains protein meal and a small amount of zinc ions, the zinc ions being present in the meal in an amount sufficient to provide about 0.003 to 0.008 parts zinc ions per part protein. . The composition has a ruminal bypass potential of greater than or equal to about 30 as measured by "% total available and undegraded protein" or "AUN%". The process for producing the composition of the invention comprises treating the meal with a small amount of zinc ions and then heating the mixture under moist heat conditions.

Description

DETAILED DESCRIPTION OF THE INVENTION Proteinaceous feed materials containing low levels of zinc and having high rumen bypass potential and methods for their production. TECHNICAL FIELD OF THE INVENTION The present invention relates to improving the nutritional value of proteinaceous meal of plant seeds such as soybean meal used to feed ruminants. More particularly, the present invention relates to improved meal compositions whose protein content is protected from degradation in the rumen of eating animals and methods of making such meal compositions. B. RELATED ART It has long been known that the feed value of feed ingredients that provide proteins is altered and adversely affected by degradation in the rumen of ruminants. This rumen degradation reduces the amount of protein ultimately available to the farm animal for metabolism. Therefore, it is believed to be advantageous to "protect" the protein component of the ruminant feed from being solubilized or metabolized in the rumen and pass through it in a substantially undegraded form. Therefore, the undegraded protein is available for digestion in the digestive system of farm animals after the rumen. Protein efficiency values in soybean meal are relatively low in terms of feed value lost to rumen destruction (see Klopfenstein, Feedstuffs, pages 23-24, July 1981). Since soybean meal is one of the major protein-containing feed ingredients utilized by ruminants, it is particularly desirable to provide a commercially viable method of protecting soybean meal from rumen destruction. Such a method should be simple, efficient and relatively low cost for large scale commercial use. Therefore, such a method must be able to be incorporated into existing commercial equipment for processing soybeans and the like into feed ingredients. Several methods have previously been attempted in an attempt to protect the protein content of ruminant feed. For example, US Pat. No. 3,619,200 proposes to apply a rumen resistant coating to ruminant proteinaceous feed ingredients such as plant meal. The purpose of this coating is to protect the proteinaceous feed from bacterial attack in the rumen, and then to degrade the coating to digest the feed in the abomasum and small intestine. It is also known that the solubility of proteins in ruminant feed ingredients can be reduced by treating the feed ingredient with tannins, formaldehyde or other aldehydes. Moreover, the solubility of the protein can be reduced by heating the protein. These methods are summarized in US Pat. No. 4,186,213 and references cited therein. Feed ingredients that can be treated using one or more of these methods to reduce the solubility of the protein in the rumen and protect against rumen destruction include various plant meals. Is disclosed. Other important prior art documents are: Hudson et al. Anim. Sci, 30: 609-613, 1970; Tagari et al., Brit. J. Nutr., 16: 237-243, 1982; Anderson, U.S. Pat. No. 3,463,858 (1969); Emery et al., U.S. Pat. No. 2,295,643 (1942); Ashmead U.S. Pat. No. 4,172,072 (1979). Meyer, U.S. Pat. No. 4,664,905 (1987); Hudson et al. Reported that commercial soybean meal (70% N soluble) and soybean meal (35 %% N soluble) after heating at 140 ° C for 4 hours, nitrogen utilization after rumen in small sheep. The experimental results comparing the above are described. The results show that heated meal has a low rate of microbial degradation in the rumen. Tagari et al. Compared the solvent-extracted soybean meal with different heat exposures. This test included solvent removal at room temperature, 80 ° C for 10 minutes, and steaming commercial toasted meal at 120 ° C for 15 minutes. These meals were given to rams and then ruminal fluid tested. A comparison of artificial rumen for ammonia release was also performed. It was concluded that a major factor in determining the different efficiencies of processed soybean meal over unprocessed soybean meal was their different solubilities in rumen fluid. It was also observed that the change in solubility caused by different heat treatments of soybean meal was relatively large compared to other meals. Of particular importance to the present invention is the method of adding substances such as zinc to feed ingredients and the compositions obtained by this addition. Anderson discloses a method for producing growth factors used to raise livestock and poultry. A zinc salt in an aqueous solution such as zinc chloride or zinc sulfate is reacted with free amino acids of a proteinaceous feed ingredient. The reaction is carried out in an aqueous solution having a temperature of 60-70 ° C (140-158 ° F) and a pH of 3.5. This pH is ZnCl ₂ In the case of, the pH is adjusted automatically with other zinc salts using HCl. The reaction mixture is dried to a moisture content of 2-8% and then mixed with the feed. There is no mention of feeding ruminants or protecting the rumen with proteins. The Emery et al. Patent describes the following method. That is, mineral compounds, including zinc and other polyvalent metal oxides, hydroxides and salts, are added to water and proteins that decompose proteins such as H. ₃ PO _Four , HCl or H ₂ SO _Four The method of reacting with a proteinaceous feed material in the presence of The reaction mixture is dried by heating in air. Soybean meal is pointed out as the preferred feed ingredient, and among the polyvalent metals, zinc is stated to be used in the form of oxides, hydroxides or carbonates. Other salts, such as cobalt salts, are indicated to be used in the form of their hydrochloride or sulphate salts. The example illustrates the reaction of a large amount of metal compound with soybean meal (Example 1 used 35% metal compound and Example III used 17% metal compound). However, there is no mention of rumen protection and nutritional value in this patent. The Ashmead patent proposes the use of metalloprotein compounds to replenish human and animal mineral deficiencies. This protein compound is produced by reacting a salt of a divalent metal under alkaline pH with a free amino acid of a protein hydrolyzed by an enzyme. Meyer, in U.S. Pat. No. 4,664,905, discloses adding zinc to a proteinaceous feed, where the zinc is added in an aqueous solution or in a dry mixture, followed by steaming. The concentration of zinc ions should be in the range of 0.25 to 1.3% by weight, based on the dry weight of the meal. The industry was already aware of the use of zinc as an agent for the protection of protein content in plant feeds and the like, but the use of zinc resulted in certain drawbacks. In particular, there has been a concern about excretion of heavy metals such as zinc into the environment in animal excrement. In response to these concerns, nations around the world have established regulatory limits on the maximum permissible levels of zinc in protein feed meal. Therefore, there is a need for a feed composition that incorporates low levels of zinc relative to currently used compositions and that exhibits favorable rumen bypass properties, and methods of making the same. It is highly desirable that such a method be easily incorporated into existing equipment for processing soybeans, etc., and it would be even more advantageous if it could be carried out in remote areas such as cattle feeding areas without the need for large-scale equipment. is there. Accordingly, it is an object of the present invention to provide a protected feed composition having relatively low levels of zinc uptake but exhibiting favorable rumen bypass properties. Another object of the present invention is to provide a method for producing a protected feed composition as described above, which can be easily incorporated into an existing commercial facility for processing soybean and the like and can be carried out at a remote place. is there. SUMMARY OF THE INVENTION During the experimental studies associated with the development of the present invention, the rumen bypass potential normally obtained by including 0.015 to 0.02 parts zinc per part protein in meal using the dry mix method is It was discovered that contacting defatted soy flakes under moist heat conditions resulted in a 60-70% reduction in zinc content, obtained by using only about 0.003 to 0.008 parts zinc per part protein in soybean meal. . Under such conditions, the total water content of the zinc / meal mixture will be in the range of 15-30%, with a total water content of about 20% being preferred. Heating the zinc / meal mixture can be carried out using a commercial toaster at a temperature of 180-230 ° F for about 10-30 minutes. This heating can also be carried out at a temperature of 280-300 ° F using a combined roaster / conditioner. It has also been surprisingly found that heating can be carried out for much shorter times with a commercial extruder to obtain a similar rumen bypass potential. Enzyme indigestion, determined by measuring the rate and extent of protease-induced protein degradation in vitro, is a useful tool for assessing the rumen bypass potential of various diets. Suitable test methods are described in J. Anim. Sci. Abstra., 679, 379, 1980, Poos et al., "Comparison of laboratory approaches for predicting rumen degradation of protein supplements"; Anim. Sci. Abstra., 121, 118, 1998, Rock et al., "Evaluation of Enzymatic Proteolysis". Utilizing in vitro enzymatic degradation as a predictor of potential rumen degradation, a set of standard protein supplements whose true ruminal bypass properties were determined in bovine rumen fistulas. Was established by applying for. The preferred enzyme is ficin. Ficin was used in the tests described below. The values measured by the ficin enzyme test are given in "percentage of total protein available and not degraded" or "% AU N". Table I shows typical AUN values for feed treated according to the present invention. BRIEF DESCRIPTION OF THE FIGURES FIG. 1 is a flow sheet for practicing the method of the present invention in a typical soybean processing facility where zinc is added prior to introducing the meal into the desolventizer-toaster. FIG. 2 is a flow sheet for carrying out the method of the present invention in a general soybean processing facility, in which zinc is added before introducing the meal into the desolventizer-toaster-dryer-cooler. FIG. 3 is a flow sheet diagram when the method of the present invention is carried out in a general soybean processing facility, and zinc is introduced after the meal is desolvated and toasted. FIG. 4 is a flow sheet diagram for practicing the method of the present invention beginning with dry toast meal. FIG. 5 is a flow sheet diagram for carrying out the method of the present invention using an additional extrusion device. FIG. 6 is a flow sheet diagram when the method of the present invention is carried out at a location remote from a commercial processing facility using an extruder. FIG. 7 is a flow sheet diagram when the method of the present invention is carried out in a batch system. FIG. 8 is a graph showing milk production of animals fed a meal treated with low levels of zinc: animals fed a control meal. FIG. 9 is a graph showing milk production of animals processed with extruders and fed with meals containing low levels of zinc: animals fed control meal. DESCRIPTION OF PREFERRED EMBODIMENTS The method of the present invention can be practiced with any proteinaceous plant seed meal. Such meals include soybean meal, cottonseed meal, peanut meal, sunflower seed meal, canola (rapeseed) meal, palm kernel meal, corn gluten meal, sap meal, safflower meal and other high protein seed meals and their A mixture is included. The present invention is applicable to defatted, non-toasted soybean flakes called "white flakes" as well as toasted soybean meal. Based on current information, the best rumen protection appears to be obtained when the present invention is applied to defatted and toasted high protein plant meals, especially toasted soybean meal. Generally, toasting means heating protein meal after degreasing. A description of toast can be found in Sipos and Witte; "Desolventizer for Soybean Oil Meal-Toaster Process"; of the Am. Oil Chem. Soc., 38, 11 (1961) and Mustakas, Moulton, Bakerand Kwolek; "Desolventizing-toasting soybean meal for food-a critical process element"; of the Am. Oil Chem. Soc., 58,300 (1981). For other seed meal treatments, see AM. Altschul, eds., "Processed Plant Protein Foods"; Academic Press, New York, 1958. Patents describing processes for defatting protein meal and subsequent processing for removing solvent and toasting defatted meal include: U.S. Patents 3,268,335, 2,710,258, No. 2, 585,793. The method of the invention is particularly beneficial when applied to a defatted protein meal, although the method has been described primarily in connection with such meals, it may also be applied to a full fat or partially defatted protein product. . The method may also be practiced with related seed material such as beer meal or distilled meal which is a by-product of barley, corn and other seed grain fermentations. The zinc treating agent is preferably zinc sulfate monohydrate, but other anti-animal edible zinc salts such as zinc acetate or zinc oxide can also be used. The zinc salt can be used in an amount corresponding to 0.003 to 0.008 parts of zinc ion to 1 part of protein in meal, preferably 0.005 parts of zinc to 1 part of protein. Higher levels of zinc can be used but are not required. In fact, excess zinc should be avoided for the purposes of the present invention. This will generally result in reduced rumen bypassability of the processed protein, although lower levels can also be used. In general, the method of the present invention can be carried out either in a batch process in an oil seed processing plant, a continuous process, or a continuous process at a location remote from the oil seed processing plant. Various process configurations are possible for each of these processing types. For example, referring to FIG. 1, the method of the present invention can be implemented as a continuous process for use in an oil seed processing plant. In an example of the process, the zinc salt is added to the soybean meal before the meal is desolvated. First, soybean flakes 10 are introduced into the extraction device 12. Zinc 16 is then added to the solvent wet flakes 14 in an amount equal to about 0.003 to 0.008 parts zinc ion to 1 part protein in flakes 14 to form a zinc / flake mixture 18. Zinc 16 may be added in the form of either a dry zinc salt or a zinc salt solution. The mixture 18 is then introduced into a desolventizer-toaster (“DT”) 20. Desolventizer-In toaster, favorable conditions are maintained for the process of protecting soybean meal with zinc ions. The total water content of the meal is in the range of 15-30%, but the preferred water content is about 20%. The residence time of the meal in the toaster may be in the range of about 10-30 minutes, but preferably about 17-20 minutes, during which the meal can reach a temperature of about 180-230 ° F. Conditions are typically 220 ° F and 20 minutes, with residence time being a function of processing speed. The average residence time in the DT is about 20 minutes as most processing plants increase throughput to the limit. To achieve longer residence times, the processing plant will slow down. Longer residence times improve the bypassability of low level zinc treated soybean meal or other protein meals. The toasted meal 22 exits the DT 20 and is introduced into the dryer 24. The dryer typically includes a conveyor that moves a feeder through the dryer while applying heated air to the feed. The dryer may be a rotary tray dryer. Dry air is supplied to the feeder end of the dryer 24 by a fan 64, which draws room air through a filter 66 and passes the filtered air through an indirect steam heater 68. The dryer 24 is preferably arranged such that the drying is complete by the time the meal reaches the center of the dryer. The fan 70 can be used to introduce cooling air into the center of the dryer. The combined dry air and cooling air are exhausted from the dryer 24 by an exhaust fan 72. The exhaust air passes through a cyclone separator 74, where solid waste is removed before the air is exhausted to the atmosphere. The dried and toasted meal 26 coming out of the dryer 24 is protected against rumen degeneration and is ready for pulverization and sizing in the granulator-mill 28. There is. The meal can then be packaged or mixed with further other feed ingredients. As can be seen in FIG. 2, a similar embodiment can be carried out with a desolventizer-toaster-dryer-cooler (DTDC) 30. Toasting is performed in the desolventizer-toaster section of DTDC, while drying is performed in the dryer-cooler section. Therefore, no external drying is required. The conditions in the dryer-cooler section of the DTDC are similar to those described with respect to FIG. As can be seen in FIG. 3, zinc 16 can alternatively be mixed with the toasted soybean meal after the meal has been extracted and desolvated. Zinc 16 is added to desolvent meal 32 to form a zinc / desolventized meal mixture 34. As stated above, zinc can be added in the form of dry zinc salt or zinc salt solution in the amounts described above. The mixture 34 is conveyed to a toaster device 36, which in its internal arrangement is very similar to a DT. Inside the toaster 36, the mixture 34 is subjected to about 20% humidity and 220 ° F. for about 20 minutes. The heated zinc / meal mixture 38 exits the toaster 36 and is then dried in a typical soybean meal dryer 24. As can be seen in Figure 4, the method of the present invention can also start with dried and toasted soybean meal. Dried and toasted meal 40 from storage bin 42 is mixed with zinc 16. Zinc is supplied either as a dry zinc salt with the addition of water separately or as an aqueous zinc salt solution. The respective amounts of zinc and water must be balanced to provide the desired level of zinc ions while raising the water content of the toasted soybean meal to about 20% on the other hand. The moist meal / zinc mixture 44 is heated in a toaster apparatus at about 220 ° F for about 20 minutes. The toasted meal then passes through dryer 24 and granulator-mill 28 as described above with respect to FIG. Oil seeds such as rapeseed (canola), safflower seeds, cottonseed seeds, and peanuts are processed differently than soybean meal. The oil seeds are first pressed through an expeller that removes most of the oil. The oil seed cake contains 5-10% oil. This oil is recovered using solvent extraction in a manner similar to that normally used for soybean oil. This meal can then be heat treated using the process described in FIGS. 1, 2, 3 and 4 as described above. As can be seen in Figure 5, the continuous process in the oil seed treatment facility can also be carried out using a commercial extruder. In this process, as described in FIGS. 1 and 2, zinc 16 in the form of a zinc salt or zinc salt solution is solvent wet as the flakes exit the extractor 12 before entering the DT or DTDC. It can be added to flakes 14. Alternatively, zinc 16 may be added after the meal leaves DT or DTDC. In each case, the desolvated / toasted zinc / meal mixture 43 is introduced into an extruder 46 (more fully described therein), where it is rapidly heated to elevated temperatures. Residence time in the extruder is very short, typically between 5 and 30 seconds. After exiting the extruder 46, the heated material then goes to the dryer / cooler 24, from which it is granulated-mill prior to being packaged or further mixed with other feed ingredients. Taken to 28. Each of the above processes is typically a commercial soybean meal process due to availability in equipment such as large scale commercial toasters, desolventizers-toasters or desolventizers-toasters-dryers-chillers. Used in connection with processing equipment. However, as shown in FIG. 6, it is also possible to perform an instant process at a remote location by utilizing an extruder conditioner. As is apparent in FIG. 6, the dried protein meal 40 is stored in the storage box 42. Zinc 16 in either dry salt or zinc salt solution is then added to the dry meal to form a meal / zinc mixture 50. The mixture 50 is then introduced into the extruder device 50. As used herein, the term extruder includes equipment, commercial expellers and expanders known to those skilled in the art. Such devices include large screw type mills in which the wet material is conveyed to the end of the extruder feeder, which has wide blades on the screw to allow the wet mixture to pass easily. It As the mixture advances through the extruder under the rotational movement of the screw, changing the pitch of the screw blades results in an increase in frictional force, which in turn causes an increase in pressure and temperature. The narrow exit end of the extruder is bounded by a cap plate with preformed holes. Therefore, the meal is extruded through the preformed holes at enormous pressure, and even at 265-325 ° F. The residence time of the meal in the heating device is typically 5-30 seconds, which is considerably shorter than the residence time in the toaster described above. Wenger is a typical extruder ^TM , Sprout-Bauer ^TM , And Insta-Pro ^TM An extruder manufactured by Wenger ^TM In the extruder, temperatures of 280-325 ° F are preferred. Sprout−B auer ^TM Made and Insta-Pro ^TM In the extruder, temperatures of 265-290 ° F are preferred. Referring to FIG. 6, if dry zinc salt is used, then water or steam 52 is separately added into extruder unit 46 to produce a preferred water content of about 20%. In the extruder, the meal / zinc mixture is rapidly heated to high temperatures. The treated meal 54 exits the extruder unit 46 and is subsequently passed through the dryer 24, the chiller 56, and the granulator-mill 28. No toaster is required in this process, making it feasible to carry out the process outside of commercial processing equipment. Furthermore, the wet heat treatment in the extruder 46 takes considerably less time than the treatment in DT or DTDC or toaster. Finally, if desired, the expeller can be equipped with dies and rapid cutting equipment, which allows the extruded feed to be directly molded and pelletized. The instant process can also be carried out batchwise as described in FIG. In this arrangement, dried protein meal 40 is stored in storage box 42. Water and zinc salt 16 are added either separately or as an aqueous solution to achieve the desired zinc content, as described above, and a total water content of about 20%. The meal 40, zinc 16, and water can be introduced into the mixer 58 where they are thoroughly mixed. The resulting mixture 60 is introduced into a batch cooker 62 where it is heated at 220 ° F for about 20 minutes. The total residence time in the cooker is slightly longer than 20 minutes due to the time required for the cooker to reach the required temperature of 220 ° F. The contents of the cooker must be poured hot from the batch cooker to take advantage of the flash evaporation of water remaining in the mixture. Upon exiting the batch cooker, the meal passes through dryer 24 and exits where it is packaged. In the most preferred embodiment of the process of the present invention, the protein meal can be heated in a roaster / conditioner combination, a device that was previously used to roast and condition whole beans. A typical device is manufactured by Jet-Pro, Inc., located in Atchison, Kansas. Other process adjustments are similar to those shown in FIG. 7, except that the cooker 62 is replaced by a roaster / adjuster. To carry out this process, defatted, partially defatted or full fat protein meal is heated in a continuous flow roaster with or without zinc, followed by an isolated continuous flow conditioning. Conditioning of the meal is carried out in the chamber under moist heating conditions using low levels of zinc. In the hot air roaster, the meal is dragged across the grate floor by a drag conveyor. Air heated to a temperature of 400-500 ° F by a gas burner is passed through a grate bed to heat the meal as it is transported through the oven. The residence time of the meal in the oven was 2-5 minutes, which was sufficient time to heat the meal to 280-300 ° F. The heated meal then exits the hot air oven and enters an isolated continuous flow conditioning chamber. Once the meal enters the conditioning chamber, water or a zinc solution is added depending on whether the zinc was previously mixed with the meal. The meal moves through the conditioning room by a series of drag conveyors. In the conditioning chamber, the meal is heated for a considerable length of time, generally about 30-60 minutes, preferably about 40 minutes. A cooling fan can be used to reduce the temperature of the meal / zinc mixture to ambient temperature. The meal, which has been treated with low levels of zinc under moist heat conditions, exits the device through an exit duct. As mentioned above, the method can be applied to any defatted, partially defatted or full fat protein meal. Application to the present method using partially defatted or full fat meal can also be carried out in oil seed processing plants. For example, full-fat protein flakes, such as soy flakes, are mixed with either dry zinc salt or a zinc salt solution to produce suitable levels of zinc ions and then passed through an expander. The expander is operated at elevated temperatures in the range 220 ° F to 280 ° F with the required water added in the form of steam. This elevated temperature can cause the added water to evaporate instantly. The full fat meal can also be toasted in a desolventizer-toaster. The method of the present invention can also be applied to partially defatted protein meal, such as meal that has been treated in an expeller to remove some of those oils. Immediately after exiting the expeller, zinc is added to the hot meal either as a dry zinc salt or a zinc salt solution. The zinc-treated meal is then passed through an expander or expeller where it is heated to temperatures in the range 220 ° F to 280 ° F. Moisture can be added to the meal before or during this heating, if desired. Alternatively, the zinc-treated, partially defatted meal can be toasted in a desolventizer-toaster. The main difference in processing zinc-treated full-fat protein meal and partially defatted protein meal is that full-fat meal is not processed in the expeller, because the expeller squeezes the oil. The method of the present invention produces several benefits, including improved milk production, improved milk production sustainability, improved steer growth using the Limit-Gro concept, and improved steer care efficiency. These benefits are further illustrated by the examples below. Example 1 Toasted soybean meal with 48% protein was prepared. One half was untreated and served as a control. The other half was processed as follows. 48% protein soybean meal was mixed with zinc sulphate to 1875 ppm zinc ion and then exposed to 15 pounds of steam in a closed container for 20 minutes. Condensed water vapor increased the water content of the meal to about 20%. After heat treatment, water was dried to 12% in a pellet cooler equipped with a fine mesh screen, and stored in a bag until use. In vitro degradability analysis by ficin assay showed that the untreated and treated meals had 19.8% and 60.9% available undegraded nitrogen (AUN), respectively. A 42-hour test was conducted using 40 Holstein calves with an average weight of 542.3 lbs to investigate untreated and treated soybean meal as a protein source in high corn silage feed. The rumen dissolved nitrogen was supplied with 0.1 pounds of urea per day. Cows were randomly assigned to four groups based on their weight. A group of 10 calves was randomly assigned to the pen. The diets fed during the experimental period were 90.73 to 91.94% corn silage, 4.0 to 7.07% shelled corn, 1.24 to 2.86% control or treated soybean meal, 0.28 to 0.32% urea, and 0.69 to. It consisted of a 0.89% proprietary mix. Feed was provided daily. Diets containing treated soybeans gained daily weight gain (3.11 lbs treated and 3.00 lbs untreated). Increased pounds of dry material per pound were reduced in calves fed treated soybean meal (5.32 treated and 5.65 untreated). Ingestion efficiency was favored by calves fed with treated soybean meal, as intake of dry material decreased and weight increased. These data show that the preferred resulting bypass protein can be produced by treating 48% protein toasted soybean meal with a small amount of zinc and heat of wetting. Example 2 Toasted soybean meal with 48% protein was prepared. Half of it was used untreated as a control. The other half was processed as follows. Soybean meal with 48% protein was treated with zinc sulfate to 1875 ppm zinc ion and then exposed to 15 pounds of steam for 20 minutes in a closed container. Condensed water vapor increased the water content of the meal to about 20%. After heat treatment, it was dried in a pellet cooler equipped with a fine mesh screen. Fifteen batches of treated meal were prepared for testing. The 15 batches of meal were mixed well, put in a bag and stored until use. For each batch, in vitro degradability analysis by the ficin assay was performed. The results of these analyzes are shown in Table II. The AUN% of untreated soybean meal was 23.7. The untreated and treated soybean meal used in this test was also analyzed for% bypass protein per calf by the Dacron bag method. The data are shown in Table III along with in vitro ficin quantitation data. Sixty-four dairy cows were first assigned one of two experimental diets. The experimental feed consisted of complete dairy pellets with 16% protein. Wheat mids were minimized (6%) to maximize soybean meal loading. The test diets referred to as DFP-1041 and DFP-1042 contained 60% corn, 20% soybean meal and 6% wheat mid. DFP-1041 contained 48% untreated protein soybean meal, while DFP-1042 contained 48% protein soybean meal treated with a small amount of zinc ions. Both diets contained sodium bicarbonate. The test had a six-week test period after the two-week preparation period. During the test, 19 dairy cows were fed little or no grain (complete feed) and did not produce milk (by lactation). Grain intake is automatically adjusted by computer according to milk production. Dairy cows that reached a point where they had been given little or no grain for some part of the test period were released after analyzing the data. Data from 45 cows were submitted for comparison. Of the 45 dairy cows, 24 were young lactating cows for the first time and 21 were adult cows. Data for milk yield and composition are shown in Table IV. The milk yield data are summarized by block (lactation) and shown in Table V. Milk production is shown in FIG. Cows fed low-zinc treated soybean meal produced more milk at all lactations than control cows. Cows with an excess of 150 DIM at the start of the study also benefited from a diet containing soybean meal treated with a small amount of zinc. FIG. 8 shows this lactating state. Cows fed the soy meat diet treated with a small amount of zinc produced an average of 3 pounds more milk per day compared to the control diet cows. Diets treated with small amounts of zinc had no effect on milk fat and protein. Example 3 Only one lot of 48% protein toasted soybean meal was prepared. Half of the meal was untreated and served as a control. The other half was mixed with zinc sulfate so that the zinc ion content was 1875 ppm. The toasted soybean meal containing this zinc ion was added to Wenger under the following conditions. ^TM Processed on X155 extruder: Barrel-6 head; Die and peripherals; 156 round holes, 3/16 inch diameter each (three rows of holes), 54 double rows and 48 single rows; knife Had four blades. Toasted soybean meal containing zinc ions was fed at a rate of 1200 to 1300 pounds per hour. The water feed rate was 300 pounds per hour downspout, 150-1900 ° F. According to the Ficine quantitative test, the AUN% of the treated meal after extrusion was 71.5. High-producing dairy cows were subjected to a 56-day lactation study to investigate a complete grain feed containing 17% protein. One containing 17% protein complete grain feed (DFP-833) with 16.5% untreated toasted 48% soybean meal (control) and the other feed (DFP-832) treated Included 16% soybean meal with 48% toasted protein (test). Besides whole grain feed, a small amount of high moisture corn, corn silage and hayage 50 to 50 mixture, and good quality hay were provided. Between 50 and 52 Holstein cows were assigned to two groups based on milk days, milk yield, lactation frequency and% milk fat. 43 heads were studied and tested. The performance of Holstein dairy cows is shown in Table VI. According to this test, milk yields of cows fed a test diet containing soybean meal processed with an extruder and containing a small amount of zinc produced about 3 times more milk per day than cows fed the control diet. It is clearly established that there is only a pound of milk. The treated feed also maintained a high percentage of milk production throughout the test as shown in FIG. Example 4 A soybean meal cooked with 48% protein was prepared and divided into two. Half of the meal was used untreated as a control. The other half is INSTA-PRO ^TM 2000 Extruder processed. The method is as follows. Toasted soybean meal was mixed with 130 pounds of water per ton, and 80 pounds of feed grade fat. This mixture is insta-pro ^TM 2000 Extruder processed. The outlet temperature was 275 ° F. The production rate was 1800 pounds per hour. The ficin value of the treated meal was 50.7 ± 3.6%. Eighty-five Holstein cows were assigned to two groups based on days of milk (DIM), milk yield, lactation frequency, and% milk fat. For various reasons, 46 animals were tested. All cows were fed a complete dairy diet with 17% protein. During the test period (May 31-July 26), the control standard DFP-843, a complete diet containing 17% protein containing untreated toasted soybean meal, was treated with soybean meal treated with a small amount of zinc. Compared to 17% complete dairy feed DFP-842, which is equivalent to DFP-843 except that it was replaced with untreated meal. About 0.5% of urea was added to the grain feed to supply the nitrogen content of the rumen. The forage was a 50:50 mixture of corn silage and haleyage. All cows were fed good quality alfalfa hay. Milk production in cows fed the experimental diet DFP-842 was improved over cows fed the control diet, 63.2 vs. 62.6 lbs (P0.05). There was no difference in the fat and protein percentages of the milk. Although low bypass protein improved milk production, it did not reach the high level reported in Example 3 (71.54%). Example 5 A lot of toasted soybean meal with 48% protein was prepared. Half of the meal was used untreated as a control. The other half was mixed with zinc sulfate so that the zinc ion content was 1875 ppm. Toasted soybean meal containing zinc ions is Wenger under the following conditions: ^TM Processed on X155 extruder: Barrel 6 head; Die and peripherals; 156 round holes with 3/16 inch diameter each (three rows of holes), 54 double rows and 48 single rows; 4 knives It was a blade. Toasted soybean meal containing zinc ions was fed at a rate of 1200 to 1300 pounds per hour. The water feed rate was 300 pounds per hour in the downspout and was 150-190 ° C. The AUN% of the treated meal after extrusion was 71.5. Eighty (80) crossbred calves with an average weight of 704.1 lbs were assigned to eight sets of ten, each based on pedigree and weight. During the pre-test phase, corn silage feed, 5 pounds of shelled corn per head per day, and feed supplemented with 1.5 pounds of BGP-830 were provided. During the 49-day test phase, diets were made with shelled corn, corn silage, supplements, and Rumenisin-Tylan carrier and were fed well or restricted to 1.75% to 2.04% of body weight. The results of the experiment showed that the calves fed soybean meal treated with a small amount of zinc had an improved daily gain (1.94 vs 2.20 lbs) (P <0.01). The effect of changing the dry material favored calves fed soybean meal treated with a small amount of zinc (7.71 lbs vs 6.84 lbs) (P0.01). The difference in feed and dry material intake was similar for protein treatment. While a preferred embodiment of this invention has been described, it should be understood by those skilled in the art that various modifications can be made without departing from the spirit and scope of the invention recited in the claims.

─────────────────────────────────────────────────── ─── Continued front page    (81) Designated countries EP (AT, BE, CH, DE, DK, ES, FR, GB, GR, IE, IT, LU, M C, NL, PT, SE), OA (BF, BJ, CF, CG , CI, CM, GA, GN, ML, MR, NE, SN, TD, TG), AU, BB, BG, BR, BY, CA, CZ, FI, HU, JP, KP, KR, LK, MG, M N, MW, NO, NZ, PL, RO, RU, SD, SK , VN (72) Inventor Smith, Janet Swee.             United States 46807 Indiana               Fort Wayne Hoagland             Venue 5715 (72) Inventor Monaggle, Charles W.             United States 46815 Indiana               Fort Wayne Beaver Brut             Quad drive 3902

Claims (1)

[Claims] 1. It consists of protein meal and zinc salt. Present in an amount sufficient to provide about 0.003 to 0.008 parts of zinc ions per part of puff. A composition for feeding ruminant animals, and having an AUN% value of about 30 or more A composition characterized by: 2. Zinc salt gives about 0.005 parts zinc ion per 1 part protein in meal A composition according to claim 1 which is present in an amount sufficient to 3.Protein meal is soybean, rapeseed, sunflower, canola, cottonseed meal, peanut Meal, safflower meal, palm kernel meal, corn gluten meal and The composition according to claim 1, which comprises a component selected from the group consisting of blood meal and blood meal. . 4.a) The zinc salt is added to the meal in an amount of about 0.003 to 0.008 parts zinc ion per part protein. Is present in an amount sufficient to provide the protein meal. To form a mixture, and then b) heating the mixture under moist conditions, A method for producing an improved feed for ruminant comprising the following. 5. Zinc salt gives about 0.005 parts zinc ion per part protein in meal The method of claim 4, wherein the method is present in an amount sufficient to 6. The method according to claim 4, wherein the mixture is heated in the extruder. the method of. 7. The mixture is heated in the extruder at a temperature of about 265 ° F to about 325 ° F. The method described in the section. 8. Heat the mixture at a temperature of about 180 ° F to about 230 ° F for 15-30 minutes to remove the protein meal. The method of claim 4 performed in a toaster. 9. Heating of the mixture is done in a combined roaster / conditioner Method of range 4th term. 10. The method of claim 9 wherein the mixture is heated to a temperature of about 280 ° F to about 300 ° F. the method of. 11. The protein meal is toasted protein meal, claim 4. The method described. 12. Protein meal is soybean, rapeseed, sunflower, canola, cottonseed meal, peanut Raw meal, safflower meal, palm kernel meal, corn gluten meal 5. The method according to claim 4, which contains a component selected from the group consisting of . 13. A product manufactured by the method according to claim 4. 14. A product manufactured by the method according to claim 5. 15. A product manufactured by the method according to claim 6. 16. A product manufactured by the method according to claim 7. 17. A product manufactured by the method according to claim 8. 18. A product manufactured by the method according to claim 9. 19. A product manufactured by the method according to claim 10. 20. A product manufactured by the method according to claim 11. 21. A product manufactured by the method according to claim 12.